Iron overload promotes Cyclin D1 expression and alters cell cycle in mouse hepatocytes.

Background/aims: Patients exhibiting hepatic iron overload frequently develop hepatocellular carcinoma. An impaired expression of hepatic genes could be involved in this phenomenon. Our aim was to identify, during iron overload, hepatic genes involved in cell cycle which are misregulated.

Arterial wall response to ex vivo exposure to oscillatory shear stress.

Background: The aim of this study was to analyze the arterial wall response to plaque-prone hemodynamic environments, known to occur mainly in areas of arterial trees such as bifurcations and branching points. In these areas, the vasculature is exposed to cyclically reversing flow that induces an endothelial dysfunction predisposing thus arteries to local development of atherosclerotic plaques.

Methods: We used an ex vivo perfusion system that allows culturing arterial segments under different hemodynamic conditions.

Hepcidin in iron metabolism.

Hepcidin, which has been recently identified both by biochemical and genomic approaches, is a 25 amino acid polypeptide synthesized mainly by hepatocytes and secreted into the plasma. Besides its potential activity in antimicrobial defense, hepcidin plays a major role in iron metabolism. It controls two key steps of iron bioavailability, likely through a hormonal action: digestive iron absorption by enterocytes and iron recycling by macrophages.

Cap G, a gelsolin family protein modulating protective effects of unidirectional shear stress.

Atherosclerosis is a progressive and complex pathophysiological process occurring in large arteries. Although it is of multifactorial origin, the disease develops at preferential sites along the vasculature in regions experiencing specific hemodynamic conditions that are predisposed to endothelial dysfunction. The exact mechanisms allowing endothelial cells to discriminate between plaque-free and plaque-prone flows remain to be explored.